Genetic inversion in the formation of an Hfr strain from a temperature-sensitive F'' gal strain.

An Hfr strain (PB15) that carries a duplicated copy of the galactose operon genes flanking the integrated sex factor is unusually stable since it does not show excision of the repeated deoxyribonucleic acid segment. The right-hand galactose operon is in the normal orientation. Deletion mutations that eliminate the right-hand galactose genes, the sex factor, and some of the left-hand operon have been isolated. Mutants believed to have their left-hand galactose operon inverted were able to be induced for galactose epimerase synthesis by D-fucose but did not show escape synthesis on induction of bacteriophage lambda. Ribonucleic acid specific for the galactose operon was isolated after induction of lysogenic strains presumed to carry the galactose operon in the normal and inverted orientation. Hybridization to the isolated left and right strands of lambdapgal showed that the noninformational strand of the left-hand galactose operon of the deletion mutant of PB15 was transcribed on escape induction. These results show that inversion has occurred.     

Isolation of Plaque-Forming, Galactose-Transducing Strains of Phage Lambda

Plaque-forming, galactose-transducing lambda strains have been isolated from lysogens in which bacterial genes have been removed from between the galactose operon and the prophage by deletion mutation.—A second class has been isolated starting with a lysogenic strain which carries a deletion of the genes to the right of the galactose operon and part of the prophage. This strain was lysogenized with a second lambda phage to yield a lysogen from which galactose-transducing, plaque-forming phages were obtained. These plaque-forming phages were found to be genetically unstable, due to a duplication of part of the lambda chromosome. The genetic instability of these partial diploid strains is due to homologous genetic recombindation between the two identical copies of the phage DNA comprising the duplication. The galactose operon and the duplication of phage DNA carried by these strains is located between the phage lambda P and Q genes.     

Location of ribosome binding sites on the right end of lambda DNA.

The locations of ribosome binding sites on the right end of bacteriophage lambda DNA were determined by measurement of the positions of ribosomes bound to single-stranded DNA visualized by electron microscopy. A total of ten ribosome binding sites were found between map co-ordinates 0.90 and 1.0. Four of these ribosome binding sites probably correspond to the polypeptide initiation sites for genes Q (0.910), S (0.928), R (0.936) and Rz (0.945). Six other ribosome binding sites were found which presumably indicate the presence of new lambda genes. Four of these ribosome binding sites (0.958, 0.967, 0.975, 0.995) are located to the right of Rz, which is the most rightward known lambda gene. A ribosome binding site is located at 0.923, between genes Q and S, in or near the 6 S RNA sequence. Another is located left of gene Q at 0.900.     

Isolation of mutant promoters in the Escherichia coli galactose operon using local mutagenesis on cloned DNA fragments

We have worked out a system to obtain mutations that map in the promoter region of the Escherichia coli galactose operon. In order to easily detect small changes in gal promoter activity, we constructed a plasmid containing an operon fusion in which the lactose operon structural genes were controlled by the galactose operon promoter region. In cells harbouring this plasmid, even modest variations in the expression of the lac genes could be detected on MacConkey lactose indicator plates.Enrichment for mutations that map in the promoter segment of the galactose operon was achieved by mutagenesis in vitro of a small fragment of DNA covering the promoter region. After insertion of the mutagenized gal promoter fragment into the gal-lac fusion plasmid, lac^?1 cells were transformed and screened for an altered Lac⁺ phenotype on indicator plates. Several mutants were isolated due to lesions mapping in the small fragment covering the galactose promoter. In these mutants, the level of β-galactosidase was between 15 and 50% of the wild-type level.The mutant promoters were subsequently reinserted into a plasmid containing the intact galactose operon. Cells harbouring such plasmids, reconstituted with mutant galactose promoters, contained decreased levels of galactokinase that paralleled the decreases in β-galactosidase. The biochemical properties of these mutants are reported in the accompanying paper (Busby et al., 1982).     

Isolation of Lambda Transducing Phage with the bio Genes Inserted between Lambda Genes P and Q

Plaque-forming, biotin-transducing phages were constructed with the bio genes inserted between lambda genes P and Q. These phages were isolated for the eventual aim of fusing the lambda Q gene to the bio operon. The following steps were used to construct these phages: A defective temperature-sensitive lysogen was constructed with the bio genes adjacent to and to the left of lambda genes beta NcI857OPQSRA. Heat-resistant survivors were screened for deletions with endpoints in the bio operon and to the right of lambda P and to the left of lambda A. Five of approximately 1,600 heat-resistant survivors had these properties. Two had the gene order bioAB .... lambda QSRA. When these two strains were lysogenized with lambda cI857b221 and heat induced, the desired transducing phages were obtained. We characterized these phages and studied one in detail. Two-thirds of the plaque-forming transducing phages isolated carried the entire bioB gene and only part of the bioA gene, and one-third carried the entire bioA and bioB genes. The phages isolated lost the bio genes upon propagation, indicating that they contain a partial duplication of phage genes. The duplication was shown not to involve the entire lambda Q gene in one of these phages, lambda bioq1b221. A recombinant of this phage, lambda Nam7am53c17b221, failed to form plaques under biotin-derepression conditions. We conclude that if the lambda Q gene was fused to the bio operon in this phage, not enough lambda Q gene product was made to allow phage propagation.     

Plasmid vectors for positive galactose-resistance selection of cloned DNA in Escherichia coli

Insertion of a HindIII-EcoRI fragment carrying part of the gal operon from lambda gal+ into pBR322 yields a plasmid (pAA3) which confers strong galactose sensitivity on E. coli strains deleted for the gal operon. Sensitivity to galactose is caused by the expression of kinase and transferase (but not epimerase) genes from a promoter located in the tet gene of pBR322. Insertion of a DNA fragment carrying Tn9 at the HindIII junction blocks gal expression and produces a galactose-resistant phenotype. Hence, galactose resistance can be used to select DNA fragments cloned at the HindIII site. The system was used efficiently for cloning lambda, yeast, and human DNA. The cloned fragments can be screened directly for the presence of promoters by testing for tetracycline resistance. Alternatively, these plasmids can be used as cosmids for cloning large fragments of DNA at a number of sites. Construction of several related vectors is described.     

The gal Genes for the Leloir Pathway of Lactobacillus casei 64H

The gal genes from the chromosome of Lactobacillus casei 64H were cloned by complementation of the galK2 mutation of Escherichia coli HB101. The pUC19 derivative pKBL1 in one complementation-positive clone contained a 5.8-kb DNA HindIII fragment. Detailed studies with other E. coli K-12 strains indicated that plasmid pKBL1 contains the genes coding for a galactokinase (GalK), a galactose 1-phosphate-uridyltransferase (GalT), and a UDP-galactose 4-epimerase (GalE). In vitro assays demonstrated that the three enzymatic activities are expressed from pKBL1. Sequence analysis revealed that pKBL1 contained two additional genes, one coding for a repressor protein of the LacI-GalR-family and the other coding for an aldose 1-epimerase (mutarotase). The gene order of the L. casei gal operon is galKETRM. Because parts of the gene for the mutarotase as well as the promoter region upstream of galK were not cloned on pKBL1, the regions flanking the HindIII fragment of pKBL1 were amplified by inverse PCR. Northern blot analysis showed that the gal genes constitute an operon that is transcribed from two promoters. The galKp promoter is inducible by galactose in the medium, while galEp constitutes a semiconstitutive promoter located in galK.     

Gene organization and structure of the Streptomyces lividans gal operon.

We present the gene organization and DNA sequence of the Streptomyces lividans galactose utilization genes. Complementation of Escherichia coli galE, galT, or galK mutants and DNA sequence analysis were used to demonstrate that the galactose utilization genes are organized within an operon with the gene order galT, galE, and galK. Comparison of the inferred protein sequences for the S. lividans gal gene products to the corresponding E. coli and Saccharomyces carlbergensis sequences identified regions of structural homology within each of the galactose utilization enzymes. Finally, we discuss a potential relationship between the gene organization of the operon and the functional roles of the gal enzymes in cellular metabolism.     

Genome of Enterobacteriophage Lula/phi80 and Insights into Its Ability To Spread in the Laboratory Environment

The novel temperate bacteriophage Lula, contaminating laboratory Escherichia coli strains, turned out to be the well-known lambdoid phage phi80. Our previous studies revealed that two characteristics of Lula/phi80 facilitate its spread in the laboratory environment: cryptic lysogen productivity and stealthy infectivity. To understand the genetics/genomics behind these traits, we sequenced and annotated the Lula/phi80 genome, encountering an E. coli-toxic gene revealed as a gap in the sequencing contig and analyzing a few genes in more detail. Lula/phi80''s genome layout copies that of lambda, yet homology with other lambdoid phages is mostly limited to the capsid genes. Lula/phi80''s DNA is resistant to cutting with several restriction enzymes, suggesting DNA modification, but deletion of the phage''s damL gene, coding for DNA adenine methylase, did not make DNA cuttable. The damL mutation of Lula/phi80 also did not change the phage titer in lysogen cultures, whereas the host dam mutation did increase it almost 100-fold. Since the high phage titer in cultures of Lula/phi80 lysogens is apparently in response to endogenous DNA damage, we deleted the only Lula/phi80 SOS-controlled gene, dinL. We found that dinL mutant lysogens release fewer phage in response to endogenous DNA damage but are unchanged in their response to external DNA damage. The toxic gene of Lula/phi80, gamL, encodes an inhibitor of the host ATP-dependent exonucleases, RecBCD and SbcCD. Its own antidote, agt, apparently encoding a modifier protein, was found nearby. Interestingly, Lula/phi80 lysogens are recD and sbcCD phenocopies, so GamL and Agt are part of lysogenic conversion.     

The use of transgenic mice for short-term,in vivo mutagenicity testing

In order to develop a short-term, in vivo assay to study the mutagenic effects of chemical exposure, transgenic mice were generated using a lambda shuttle vector containing a lacZ target gene. Following exposure to mutagens, this target can be rescued efficiently from genomic DNA prepared from tissues of the treated mice using restriction minus, in vitro lambda phage packaging extract and restriction minus Escherichia coli plating cultures. Mutations in the target gene appear as colorless plaques on a background of blue plaques when plated on indicator agar. Spontaneous background levels were ′1 × 10⁻⁵ in each of three mouse lineages analyzed. Exposure of lambda transgenic mice to N-ethyl-N-nitrosourea resulted in as much as a 14-fold induction in detected mutations over background levels. The assay is currently being modified to incorporate lacI as the target for ease of mutation detection as well as in vivo excision properties of the Lambda ZAP vector, facilitating sequence analysis of mutant plaques.